The porcine skeletal muscle ryanodine receptor gene structure coding region 1 to 10614 harbouring 71 exons

Construction of a 1.2-Mb BAC/PAC contig of the porcine gene RYR1 region on SSC 6q1.2 and comparative analysis with HSA 19q13.13

We screened a porcine bacterial artificial chromosome (BAC) and a P1 derived artificial chromosome (PAC) library to construct a sequence-ready approximately 1.2-Mb BAC/PAC contig of the ryanodine receptor-1 gene (RYR1) region on porcine chromosome (SSC) 6q1.2. This genomic segment is of special interest because it harbors the locus for stress susceptibility in pigs and a putative quantitative trait locus for muscle growth. Detailed physical mapping of this gene-rich region allowed us to assign to this contig 17 porcine genes orthologous to known human chromosome 19 genes. Apart from the relatively well-characterized porcine gene RYR1, the other 16 genes represent novel chromosomal assignments and 14 genes have been cloned for the first time in pig. Comparative analysis of the porcine BAC/PAC contig with the human chromosome (HSA) 19q13.13 map revealed a completely conserved gene order of this segment between pig and human. A detailed porcine-human-mouse comparative map of this region was constructed.

New intra-renal graft genes associated with tolerance or rejection

BACKGROUND

Recipient type mononuclear cells infiltrating kidney allografts have different phenotypes and functions according to the fate of the graft. We hypothesized that different genetic programs were involved in rejected or accepted tissues and thus, transcripts that correlated with the clinical status could be identified by a differential expression strategy. This strategy was applied to miniature swine class II matched, class I disparate kidney grafts, which are accepted in recipient animals treated for 12 days with Cyclosporin A (CsA).

METHODS

The mRNA differential display RT-PCR technique (DDRT-PCR) was used to detect clinical status-specific transcripts. cDNA templates for this analysis were derived from biopsies of accepted (CsA treated) and rejected (untreated) kidney grafts 8 days post-transplantation.

RESULTS

A first screening procedure identified 23 PCR products differentially amplified in either tolerant or rejector samples. Nucleotide sequence of these partial transcripts showed that 11 out of 23 (48%) sequences had unknown open reading frames while 12 had substantial homology to known sequences. To validate the approach, rejection-associated (RA) cDNA 1 (RA-1) was characterized further. The results indicated that RA-1 is the porcine equivalent of secreted protein acidic and rich in cysteine (SPARC). Expression studies demonstrated that upregulation of SPARC gene transcription preceded other indicators of kidney dysfunction and correlated with the extent of graft infiltration.

CONCLUSION

DDRT-PCR appears to be a powerful technique to identify genes differentially expressed in grafted tissues that correlate with tolerance or rejection. One of the gene transcripts identified through this method, SPARC, may be a reliable marker of tissue injury consequent to cellular infiltration and rejection.

Genomic structure of the 5' end of the porcine ryanodine receptor 3 gene (RYR3)

Ryanodine receptor 3 is a calcium channel located in the membrane of the endoplasmic reticulum. We isolated eight overlapping PAC clones from the porcine ryanodine receptor 3 gene (RYR3) and determined the DNA sequences of the first and second exon together with 5.8 kb of 5' flanking region and 10.3 kb of intron sequences. By comparing the porcine genomic sequence to the human RYR3 cDNA sequence the porcine transcription start site could be mapped to a GC-rich region. Physical mapping of the isolated PAC clones revealed that the complete porcine RYR3 gene spans more than 200 kb of genomic DNA.

Intron "sliding" and the diversity of intron positions

Alignments of homologous genes typically reveal a great diversity of intron locations, far more than could fit comfortably in a single gene. Thus, a minority of these intron positions could be inherited from a single ancestral gene, but the larger share must be attributed to subsequent events of intron gain or intron "sliding" (movement from one position to another within a gene). Intron sliding has been argued from cases of discordant introns and from putative spatial clustering of intron positions. A list of 32 cases of discordant introns is presented here. Most of these cases are found to be artefactual. The spatial and phylogenetic distributions of intron positions from five published compilations of gene data, comprising 205 intron positions, have been examined systematically for evidence of intron sliding. The results suggest that sliding, if it occurs at all, has contributed little to the diversity of intron positions.